U.S. patent application number 10/195758 was filed with the patent office on 2003-01-16 for power supply device.
This patent application is currently assigned to Matsushita Electric Industrial Co., Ltd.. Invention is credited to Kajiwara, Jun, Kinoshita, Masayoshi, Sakiyama, Shiro.
Application Number | 20030011247 10/195758 |
Document ID | / |
Family ID | 19049485 |
Filed Date | 2003-01-16 |
United States Patent
Application |
20030011247 |
Kind Code |
A1 |
Kajiwara, Jun ; et
al. |
January 16, 2003 |
Power supply device
Abstract
A power supply device is provided in which, in order to increase
a rise speed of an output voltage and to suppress a voltage drop
when switching between power supply devices, during a second
operation mode in which power supply is stopped, an output switch
is turned off and a reference voltage generating circuit applies a
reference voltage Vref2, which equals a gate voltage in a steady
state during power supply (first operation mode), to the gate of an
output transistor. Thus, when entering the first operation mode,
the feedback operation of a differential operational amplifier
quickly reaches a steady state. In addition, during the second
operation mode, a switch that supplies power to the reference
voltage generating circuit and the differential operational
amplifier is open, reducing the power consumption of the power
supply device itself.
Inventors: |
Kajiwara, Jun; (Kyoto,
JP) ; Kinoshita, Masayoshi; (Osaka, JP) ;
Sakiyama, Shiro; (Kyoto, JP) |
Correspondence
Address: |
Jack Q. Lever, Jr.
McDERMOTT, WILL & EMERY
600 Thirteenth Street, N.W.
Washington
DC
20005-3096
US
|
Assignee: |
Matsushita Electric Industrial Co.,
Ltd.
|
Family ID: |
19049485 |
Appl. No.: |
10/195758 |
Filed: |
July 16, 2002 |
Current U.S.
Class: |
307/125 |
Current CPC
Class: |
H02J 9/005 20130101;
G06F 1/263 20130101 |
Class at
Publication: |
307/125 |
International
Class: |
H02H 001/00 |
Foreign Application Data
Date |
Code |
Application Number |
Jul 16, 2001 |
JP |
2001-214718 |
Claims
What is claimed is:
1. A power supply device comprising: a controlling means for
controlling an output voltage to a predetermined voltage during a
first operation mode for supplying power; a cut-off means for
cutting off the output voltage during a second operation mode for
halting the power supply; a control state-maintaining means for
maintaining a state of at least a portion of the controlling means
to be in a standby state during the second operation mode, the
standby state corresponding to a state of the portion of the
controlling means during the first operation mode.
2. The power supply device according to claim 1, wherein the
standby state is a state that is closer to the state during the
first operation mode than to the state during the second operation
mode.
3. The power supply device according to claim 1, wherein the
standby state is a state such that the amount of fluctuation of the
output voltage is less than a predetermined amount when the
operation mode switches from the second operation mode to the first
operation mode.
4. The power supply device according to claim 1, wherein: the
controlling means comprises an output transistor that generates the
output voltage according to a voltage of a control terminal; and
the control state-maintaining means is configured so that a voltage
of the control terminal is maintained at a predetermined
voltage.
5. The power supply device according to claim 1, wherein: the
controlling means comprises an output transistor that generates the
output voltage according to a current of a control terminal; and
the control state-maintaining means is configured so that the
current of the control terminal is maintained at a predetermined
current.
6. The power supply device according to claim 1, wherein: the
controlling means comprises a capacitor element that stores
electric charge; and the control state-maintaining means is
configured so that voltages at both ends of the capacitor element
is maintained at a predetermined voltage.
7. The power supply device according to claim 1, further comprising
a current consumption-reducing means for reducing the current
consumption of a portion of the controlling means that does not
affect the operation of the control state-maintaining means during
the second operation mode.
8. The power supply device according to claim 7, wherein the
current consumption-reducing means is configured to cut off a
current supply to a portion of the controlling means that does not
affect the operation of the control state-maintaining means.
9. The power supply device according to claim 7, wherein the
portion of the controlling means that does not affect the operation
of the control state-maintaining means includes a feedback circuit
to which the output voltage is fed back, the feedback circuit
generating a control signal for controlling the output voltage.
10. The power supply device according to claim 1, wherein the
current supply to the controlling means and the control
state-maintaining means is cut off during a third operation
mode.
11. The power supply device according to claim 1, wherein: the
controlling means comprises an operational amplifier; and the power
supply device further comprises a bias current controlling means
for controlling a bias current in the operational amplifier.
12. The power supply device according to claim 11, wherein the bias
current is controlled according to the output current of the power
supply device.
13. The power supply device according to claim 12, wherein the bias
current is controlled such that the larger the output current of
the power supply device is, the larger the bias current.
14. The power supply device according to claim 1, wherein the state
corresponding to the first operation mode is configured to be
variable in a plurality of kinds of states.
15. The power supply device according to claim 14, wherein the
plurality of kinds of states are set according to the magnitude of
a load current during the first operation mode that is after the
second operation mode.
16. A power supply device comprising: a plurality of unit power
supply devices supplying electric power to a given node of an
apparatus to which power is to be supplied; wherein at least one of
the plurality of unit power supply devices is the power supply
device according to claim 1 that is a power supply device capable
of maintaining a standby state.
17. A power supply device comprising: a plurality of unit power
supply devices supplying electric power to a given node of an
apparatus to which power is to be supplied; wherein at least one of
the plurality of unit power supply devices is the power supply
device according to claim 7 that is a power supply device capable
of maintaining a standby state.
18. A power supply device comprising: a plurality of unit power
supply devices supplying electric power to a given node of an
apparatus to which power is to be supplied; wherein at least one of
the plurality of unit power supply devices is the power supply
device according to claim 11 that is a power supply device capable
of maintaining a standby state.
19. The power supply device according to claim 16, wherein the
power supply device capable of maintaining a standby state is
switched between the second operation mode and the first operation
mode according to a load current of the apparatus to which power is
to be supplied.
20. The power supply device according to claim 19, wherein the
power is supplied by a combination of one or more of the unit power
supply devices that satisfies a current supply capability according
to the load current of the apparatus to which power is supplied and
minimizes the power consumption of the power supply device.
21. A power supply device comprising: a plurality of unit power
supply devices supplying electric power to a given node of an
apparatus to which power is to be supplied; wherein at least two or
more of the plurality of unit power supply devices are the power
supply device according to claim 1; and each of the two or more of
the plurality of unit power supply devices has a different state of
at least a portion of the controlling means that is maintained by
the control state-maintaining means from one another.
22. The power supply device according to claim 21, wherein, when
the combination of one or more of the unit power supply devices
that supplies power is changed according to a fluctuation of a load
current of the apparatus to which power is supplied, the
combination is changed into a combination such that a variation of
an output voltage is minimized.
23. The power supply device according to claim 16, wherein the
power supply device is formed in a single-chip semiconductor
integrated circuit.
24. The power supply device according to claim 1, wherein the power
supply device is formed in the same semiconductor integrated
circuit as a semiconductor integrated circuit of an apparatus to
which power is supplied.
25. A power supply device comprising: a controlling means for
controlling an output voltage for supplying electric power at a
predetermined voltage, the controlling means including an
operational amplifier; and a bias current controlling means for
controlling a bias current in the operational amplifier.
26. The power supply device according to claim 25, wherein the bias
current is controlled according to an output current of the power
supply device.
27. The power supply device according to claim 26, wherein the bias
current is controlled so that the greater the output current of the
power supply device is, the greater the bias current is.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates to a technology pertaining to
a power supply device that supplies electric power to circuits in
LSIs or in various apparatus at a predetermined controlled voltage,
such as a stabilized voltage or a second voltage that is obtained
by converting a first voltage.
[0003] 2. Description of the Related Art
[0004] In recent years, portable electronic equipment such as
mobile telephones and notebook personal computers has been coming
into widespread use. One of the keys for the portable electronic
equipment to attain widespread use is an improvement in battery
operating time, in which devices can operate with batteries. Thus,
reducing power consumption of LSIs or the like in the equipment is
an important issue in the art.
[0005] An example of a technique used to reduce power consumption
is as follows. In the field of LSIs used in mobile telephones, for
example, such a technique is used in which an LSI itself has two or
more operation states; specifically, for example, during talk time,
the LSI is operated in an active state, whereas during standby
time, it is operated in a standby state, in which only retention of
information is possible. For power supply devices, such a
configuration as follows is employed at times. During the standby
state, in order to reduce the power consumption of the power supply
device itself, a power supply device is operated in a low power
supply state, in which power supply is small and power consumption
is low, whereas during the active state, it enters a normal power
supply state, in which a large power can be supplied.
[0006] An example of the power supply device having two power
supply states such as described above is disclosed in Japanese
Unexamined Utility Model Publication 61-84923. As shown in FIG. 25,
this device has a configuration in which the voltage of a power
supply 901 is stepped down by a voltage regulating circuit 902 or a
voltage correcting circuit 903 composed of a plurality of diodes to
supply the voltage to a load 904. This power supply device is
configured so that, when the load current is large, electric power
is supplied from the voltage regulating circuit 902, which is
selected by a switching circuit 905 in response to a switch
controlling signal 906 (normal power supply state). On the other
hand, during no load condition or a light load condition in which
the load current value is small, a stepped-down voltage is supplied
by the voltage correcting circuit 903 (low power supply state).
Thus, during a light load condition or no load condition in which
the quiescent current consumption in the power supply device itself
is noticeable, for example, the power in the voltage regulating
circuit 902 is reduced so that the quiescent current 907 becomes
negligible, in order to achieve a higher current efficiency over a
wide range of load current.
[0007] The power supply device disclosed in Japanese Unexamined
Patent Publication 11-219586 is also known. In this device, as
shown in FIG. 26, a voltage converting circuit 920 is used (low
power supply state) when an apparatus that requires electric power
is in a standby state whereas a voltage converting circuit 921 is
used (normal power supply state) when the device is in an active
state. The voltage converting circuit 921 is so configured that
when power supply is to be stopped, output transistor switches 921b
to 921d are sequentially turned off under the control of a delay
circuit 921a to reduce the output current gradually (in a stepwise
manner), thus reducing the noise that is generated at the switching
between the voltage converting circuits 920 and 921.
[0008] These conventional power supply devices, however, have at
least the following drawbacks. For example, when the power supply
device is switched to the normal power supply state or to the low
power supply state, the states of various portions therein, such as
a feedback circuit, do not immediately enter a steady state, and
therefore, a sufficient current supplying capability cannot be
obtained immediately after the switching. Consequently, a temporary
voltage drop of the output voltage is caused, which leads to
unstable operations in the apparatus or the like in which the power
supply device is incorporated. Therefore, when stepwise
fluctuations (increase or decrease) in the load current occur, for
example, when the apparatus or the like shifts from a standby state
to an active state, it is difficult for the power supply device to
switch between the normal power supply state and the low power
supply state so as to respond to the load fluctuations. In
addition, even when a power supply device is used as a single unit,
(i.e., when the switching between a plurality of power supply
states does not occur), the rise of the output voltage is slow at
the start of power supply, which is another problem.
[0009] For the purpose of, for example, reducing a voltage drop in
the output voltage as described above, it may appear to be
conceivable to adopt a technique such that response characteristics
of the power supply device are increased to attain a steady current
supply state quickly, or a technique such that a capacitor having a
large capacitance is provided at the output terminal of the power
supply device to complement the supply current. However, on the one
hand, the technique of increasing response characteristics
necessitates a larger quiescent current consumption in the power
supply device itself, which considerably reduces current efficiency
during the normal power supply state. On the other hand, the
technique of employing a capacitor with a large capacitance causes
increases in the chip area and chip cost, for example, which make
it difficult to integrate the capacitor in the LSI to attain a
one-chip device.
SUMMARY OF THE INVENTION
[0010] In view of the foregoing and other problems in the prior
art, it is an object to the present invention to provide a power
supply device in which the output voltage can rise fast, an output
voltage drop can be avoided or reduced at the switching between
current supply states or the like, a high current efficiency can be
achieved over a wide range of load current without causing a
considerable increase in the quiescent current consumption in the
power supply device itself, and moreover the device can be easily
integrated into a single chip.
[0011] In order to accomplish the foregoing and other objects, the
present invention provides a power supply device comprising: a
controlling means for controlling an output voltage to a
predetermined voltage during a first operation mode for supplying
power; a cut-off means for cutting off the output voltage during a
second operation mode for halting the power supply; a control
state-maintaining means for maintaining a state of at least a
portion of the controlling means to be in a standby state during
the second operation mode, the standby state corresponding to a
state of the portion of the controlling means during the first
operation mode.
[0012] In the above-described power supply device, the standby
state may be a state that is closer to the state during the first
operation mode than to the state during the second operation
mode.
[0013] In the above-described power supply device, the standby
state may be a state such that the amount of fluctuation of the
output voltage is less than a predetermined amount when the
operation mode switches from the second operation mode to the first
operation mode.
[0014] In the above-described power supply device, the controlling
means may comprise an output transistor that generates the output
voltage according to a voltage of a control terminal; and the
control state-maintaining means may be configured so that a voltage
of the control terminal is maintained at a predetermined
voltage.
[0015] In the above-described power supply device, the controlling
means may comprise an output transistor that generates the output
voltage according to a current of a control terminal; and the
control state-maintaining means may be configured so that the
current of the control terminal is maintained at a predetermined
current.
[0016] In the above-described power supply device, the controlling
means may comprise a capacitor element that stores electric charge;
and the control state-maintaining means may be configured so that
voltages at both ends of the capacitor element is maintained at a
predetermined voltage.
[0017] With the above-described configurations, during the second
operation mode in which power supply is stopped, at least the state
of a portion of the controlling means, for example, the gate
voltage of the output transistor, a base current, a charge stored
in the capacitor, or the like, is maintained to be a state
corresponding to a state during the first operation mode.
Accordingly, when entering the first operation mode in which power
is supplied, a steady control state of the output voltage is
quickly reached, and therefore, a rise time of the output voltage
or the like can be shortened and the response characteristic at the
start of the power supply can be improved.
[0018] The above-described power supply device may further
comprises a current consumption-reducing means for reducing the
current consumption of a portion of the controlling means that does
not affect the operation of the control state-maintaining means
during the second operation mode.
[0019] In the above-described power supply device, the current
consumption-reducing means may be configured to cut off a current
supply to a portion of the controlling means that does not affect
the operation of the control state-maintaining means.
[0020] In the above-described power supply device, the portion of
the controlling means that does not affect the operation of the
control state-maintaining means may include a feedback circuit to
which the output voltage is fed back, the feedback circuit
generating a control signal for controlling the output voltage.
[0021] With the above-described configurations, the current
consumption of the portion, such as a feedback circuit, that is
required to operate only during the power supply is lowered by, for
example, cutting off the current supply to that portion, and
consequently, the current consumption of the power supply device
itself can be reduced without degrading the response characteristic
described above.
[0022] In the above-described power supply device, the current
supply to the controlling means and the control state-maintaining
means may be cut off during a third operation mode.
[0023] With the above-described configuration, the power supply
device can be configured not to consume electric power in such a
case that a high response characteristic at the start of power
supply is not required. In addition, by preventing currents from
flowing into the power supply device, a leakage test can be easily
conducted to confirm if there is no leakage current.
[0024] In the above-described power supply device, the controlling
means may comprise an operational amplifier; and the power supply
device may further comprise a bias current controlling means for
controlling a bias current in the operational amplifier.
[0025] In the above-described power supply device, the bias current
may be controlled according to the output current of the power
supply device.
[0026] In the above-described power supply device, the bias current
may be controlled such that the larger the output current of the
power supply device is, the larger the bias current.
[0027] With the above-described configurations, the response
characteristic at the start of power supply can be further improved
by increasing the bias current and the current consumption of the
power supply device itself can be reduced by reducing the bias
current. In particular, both a high speed response characteristic
against sudden load fluctuations and a power consumption reduction
in cases of relatively gradual load fluctuations, for example, can
be achieved by controlling the bias current according to the output
current of the power supply device.
[0028] In the above-described power supply device, the state
corresponding to the first operation mode may be configured to be
variable in a plurality of kinds of states.
[0029] In the above-described power supply device, the plurality of
kinds of states may be set according to the magnitude of a load
current during the first operation mode that is after the second
operation mode.
[0030] With the above-described configurations, the state of the
controlling means is set in various ways according to the magnitude
of the load current or the like when entering the first operation
mode, and as a result, the control of the output voltage is started
more appropriately. Thus, the response characteristic at the start
of power supply can be improved according to various load current
fluctuations.
[0031] In accordance with another aspect of the present invention,
a power supply device is provided comprising: a plurality of unit
power supply devices supplying electric power to a given node of an
apparatus to which power is to be supplied; wherein at least one of
the plurality of unit power supply devices is such a power supply
device as descried above that is a power supply device capable of
maintaining a standby state.
[0032] With the above-described configuration, good response
characteristic can be obtained when the power supply device enters
the first operation mode in which the device supplies power, and
therefore, it is possible to easily suppress a transient voltage
drop in the voltage supplied to the load circuit.
[0033] In the above-described power supply device, the power supply
device capable of maintaining a standby state may be switched
between the second operation mode and the first operation mode
according to a load current of the apparatus to which power is to
be supplied.
[0034] With the above-described configuration, a current
corresponding to the load current can be easily supplied.
[0035] In the above-described power supply device, the power may be
supplied by a combination of one or more of the unit power supply
devices that satisfies a current supply capability according to the
load current of the apparatus to which power is supplied and
minimizes the power consumption of the power supply device.
[0036] With the above-described configuration, a current
corresponding to the load current can be easily supplied as
described above, and in addition, the electric power consumed in
the power supply device itself can be easily reduced.
[0037] In accordance with further another aspect of the present
invention, a power supply device is provided comprising: a
plurality of unit power supply devices supplying electric power to
a given node of an apparatus to which power is to be supplied;
wherein at least two or more of the plurality of unit power supply
devices comprises one of the above-described power supply devices;
and each of the two or more of the plurality of unit power supply
devices has a different state of at least a portion of the
controlling means that is maintained by the control
state-maintaining means from one another.
[0038] In the above-described power supply device, when the
combination of one or more of the unit power supply devices that
supplies power is changed according to a fluctuation of a load
current of the apparatus to which power is supplied, the
combination may be changed into a combination such that a variation
of an output voltage is minimized.
[0039] With the above-described configurations, the control of the
output voltage can be started more appropriately by bringing the
power supply device in which the state of the controlling means
accords with the magnitude of the load current or the like into the
first operation mode. Consequently, the response characteristic at
the start of power supply can be improved according to various load
current fluctuations, and therefore, it is possible to easily
suppress a transient voltage drop in the voltage supplied to the
load circuit.
[0040] In addition, the above-described power supply device may be
formed in a single-chip semiconductor integrated circuit.
[0041] In the above-described power supply device, the power supply
device may be formed in the same semiconductor integrated circuit
as a semiconductor integrated circuit of the apparatus to which
power is supplied.
[0042] With the above-described configurations, size reduction can
be easily achieved in the power supply device as described above
that supplies power according to the load current and that is
capable of suppressing the power consumed by the power supply
device itself. In addition, the capacitance of the power supply
capacitor (bypass capacitor) is also reduced since good response
characteristic can be obtained, and as a result, the power supply
capacitor is easily integrated so that reductions in fabrication
cost and in the device size can be achieved.
[0043] In accordance with yet another aspect of the invention, a
power supply device is provided comprising: a controlling means for
controlling an output voltage for supplying electric power at a
predetermined voltage, the controlling means including an
operational amplifier; and a bias current controlling means for
controlling a bias current in the operational amplifier.
[0044] In the above-described power supply device, the bias current
may be controlled according to an output current of the power
supply device.
[0045] In the above-described power supply device, the bias current
may be controlled so that the greater the output current of the
power supply device is, the greater the bias current is.
[0046] With the above-described configurations, the response
characteristic at the start of power supply can be further improved
by increasing the bias current and the current consumption of the
power supply device itself can be reduced by reducing the bias
current. In particular, both a high speed response characteristic
against sudden load fluctuations and a power consumption reduction
in cases of relatively gradual load fluctuations, for example, can
be achieved by controlling the bias current according to the output
current of the power supply device.
BRIEF DESCRIPTION OF THE DRAWINGS
[0047] FIG. 1A is a circuit diagram showing the configuration of a
power supply device according to Embodiment 1 and the state during
the first operation mode, and FIG. 1B is a circuit diagram showing
the configuration of a power supply device according to Embodiment
1 and the state during a second operation mode.
[0048] FIG. 2A is a circuit diagram showing the specific
configuration of a power supply device according to Embodiment 1
and the state during the first operation mode, and FIG. 2B is a
circuit diagram showing the specific configuration of a power
supply device according to Embodiment 1 and the state during the
second operation mode.
[0049] FIGS. 3A to 3F are circuit diagrams showing the
configuration of a reference voltage generating circuit 123 that
generates a reference voltage Vref2 in the power supply device
according to Embodiment 1.
[0050] FIG. 4 is a graph showing gate voltage and output voltage of
an output transistor 125 in the power supply device according to
Embodiment 1.
[0051] FIG. 5 is a graph showing output voltage of the power supply
device according to Embodiment 1.
[0052] FIG. 6 is a graph showing output voltage of a conventional
power supply device.
[0053] FIG. 7 is a circuit diagram showing the configuration of a
power supply device according to Embodiment 2.
[0054] FIG. 8 is a circuit diagram showing the configuration of
another power supply device according to Embodiment 2.
[0055] FIG. 9 is a circuit diagram showing the configuration of
further another power supply device according to Embodiment 2 and
the state during the first operation mode.
[0056] FIG. 10 is a circuit diagram showing the configuration of
further another power supply device according to Embodiment 2 and
the state during the second operation mode.
[0057] FIG. 11A is a circuit diagram showing the configuration of a
power supply device according to Embodiment 3 and the state during
the first operation mode, and FIG. 11B is a circuit diagram showing
the configuration of the power supply device according to
Embodiment 3 and the state during the second operation mode.
[0058] FIG. 12A illustrates a quiescent current during the first
operation mode of the power supply device according to Embodiment
3, and FIG. 12B is illustrates quiescent current during the second
operation mode of the power supply device according to Embodiment
3.
[0059] FIG. 13 is a circuit diagram showing another example of the
power supply device according to Embodiment 3.
[0060] FIG. 14 is a circuit diagram showing the configuration of a
power supply device according to Embodiment 3 having a third
operation mode.
[0061] FIG. 15A is a circuit diagram showing the configuration of a
differential operational amplifier 122 in the power supply device
according to Embodiment 3, and FIG. 15B is a circuit diagram
showing the configuration of a variable bias voltage generating
circuit 434 in the power supply device according to Embodiment
3.
[0062] FIG. 16 is further another example of the power supply
device according to Embodiment 3.
[0063] FIGS. 17A to 17C illustrate the relationship between load
current and gate voltage of an output transistor 125 in a power
supply device according to Embodiment 4.
[0064] FIGS. 18A to 18C are circuit diagrams showing the
configuration of the reference voltage generating circuit 123 in
the power supply device according to Embodiment 4.
[0065] FIG. 19 is a block diagram showing the configuration of a
power supply device according to Embodiment 5 including a plurality
of unit power supply devices.
[0066] FIGS. 20A to 20C illustrate the relationship between gate
voltage of an output transistor 125 and load current during the
first operation mode, according to Embodiment 5.
[0067] FIG. 21 illustrates an example of the operation mode
transition in the power supply device according to Embodiment
5.
[0068] FIG. 22 is a schematic diagram showing an example of a power
supply device according to Embodiment 6 that is formed in an LSI
chip.
[0069] FIG. 23 is a schematic diagram showing another example of
the power supply device according to Embodiment 6 that is formed in
an LSI chip.
[0070] FIG. 24 is a diagram showing the configuration of a modified
example of the power supply device.
[0071] FIG. 25 is a circuit diagram showing the configuration of a
conventional power supply device.
[0072] FIG. 26 is a circuit diagram showing the configuration of
another conventional supply device.
DETAILED DESCRIPTION OF THE INVENTION
[0073] Preferred embodiments of the present invention are described
below with reference to the attached drawings.
[0074] Embodiment 1
[0075] Outline of the Configurations
[0076] FIG. 1A is a circuit diagram showing the configuration of a
power supply device according to Embodiment 1, illustrating the
state in which an apparatus or the like to which power is supplied
is, for example, in an active (normal operation) state. FIG. 1B
likewise illustrates the state in which the apparatus or the like
to which power is supplied is, for example, in a standby state.
[0077] In the figure, a load circuit 101 represents an apparatus or
a circuit to which electric power is supplied, and a capacitor 102
represents a power supply capacitor (bypass capacitor). The power
supply device that supplies electric power to the load circuit 101
has an active power supply device 111 (unit power supply device)
and a standby power supply device 112 (unit power supply
device).
[0078] The active power supply device 111 has a voltage converting
circuit 114 (controlling means) and an output switch 116
(cutting-off means), the voltage converting circuit 114 converting
a voltage supplied from a power supply 113 to a predetermined
controlled voltage (which includes a stepped-up or a stepped-down
voltage and substantially the same voltage), and the output switch
116 provided between the voltage converting circuit 114 and an
output terminal 115. The output switch 116 is composed of, for
example, a P-type MOS (metal oxide semiconductor) transistor, an
N-type MOS transistor, or a transfer gate using both types of
transistors, and is turned on/off in response to an operation mode
switching signal 117 so as to be switched between a state in which
electric power is supplied to the load circuit 116 (first operation
mode) as shown in FIG. 1A and a state in which the power supply is
stopped (second operation mode) as shown in FIG. 1B.
[0079] A standby power supply device 112 has a similar
configuration to the active power supply device 111, and both
devices serve the purpose of supplying electric power to the same
node of the load circuit 101. The active power supply device 111
and the standby power supply 112 differ in their driving
capabilities and their quiescent currents, and are configured so
that the operation modes are switched according to load
fluctuations. Specifically, the active power supply device 111 has
a large driving capability but a large current consumption, whereas
the standby power supply device 112 has a small current capability
but a small current consumption. Accordingly, in the case of an
active state in which the load circuit 101 consumes a relatively
large power, for example, during the operation starting-up of the
load circuit 101 or during the normal operation, the active power
supply device 111 enters the first operation mode while the standby
power supply device 112 enters the second operation mode to supply
a required power (normal power supply state). In contrast, when the
load circuit 101 is in a standby state, the active power supply
device 111 enters the second operation mode while the standby power
supply device 112 enters the first operation mode to supply a
minimum power and to suppress the power consumption of the power
supply device (low power supply state).
[0080] Specific Configuration of the Voltage Converter Circuit
114
[0081] Specifically, the voltage converting circuit 114 comprises,
for example as shown in FIGS. 2A and 2B:
[0082] a reference voltage generating circuit 121 that generates a
reference voltage Vref1 that is to be output as an output voltage
Vout;
[0083] a differential operational amplifier 112 that compares the
output voltage Vout with the reference voltage Vref1 and outputs a
voltage that corresponds to the difference therebetween;
[0084] a reference voltage generating circuit 123 (control state
maintaining means) that generates a reference voltage Vref2, which
is at substantially the same voltage as the voltage that is output
from the differential operational amplifier 122 when the voltage
converter circuit 114 is in the first operation mode and in a
steady state, as will be detailed later;
[0085] a switch group 124 comprising switches 124a and 124b for
selecting a voltage output from the differential operational
amplifier 122 or a voltage output from the reference voltage
generating circuit 123 in response to the same operation mode
switching signal 117 as that controlling the output switch 116;
and
[0086] an output transistor 125.
[0087] The gate terminal, the source terminal, and the drain
terminal of the output transistor 125 are respectively connected to
the switch group 124, the power supply 113, or the output switch
116, and the transistor outputs a voltage that is equal to the
reference voltage Vref1 according to the voltage output from the
differential operational amplifier 122 when the switch 124a enters
a conducting state. The output transistor 125 is not particularly
limited, though a P-type MOS transistor may be used, for
example.
[0088] In addition, the switch 124a is not necessarily provided
separately from differential operational amplifier 122 but may be
configured such that the output becomes a high impedance inside the
differential operational amplifier 122.
[0089] In addition, the following configuration is also possible.
The reference voltage generating circuit 121 may output the
reference voltage Vref1 and the reference voltage Vref2 in a
variable manner and at the same time may be connected to the gate
of the output transistor 125, so that it can also serve as the
reference voltage generating circuit 123.
[0090] Specific Configuration of the Reference Current Generating
Circuit 123
[0091] The reference voltage generating circuit 123, or the like,
may be configured so that for example, the voltage of the power
supply 113, or the like, can be divided using resistance elements
131 and 132 as illustrated in FIG. 3A. If this is the case, it is
desirable that the resistance value of the resistance elements 131
and 132 be as large as possible (as large as the chip area permits,
when formed in an LSI) in order to suppress the quiescent current
consumption of the power supply device itself. In addition, as
shown in FIG. 3B, it is possible to use one or more diodes 133 and
a resistance element 134 so that a voltage that is reduced by the
predetermined voltage from the voltage of the power supply 113
using a forward voltage drop in the diodes 133, or voltages at both
ends of the diodes 133 may be used. The diode 133 may be composed
of transistors 135 in each of which the gate is connected to the
drain, as shown in FIG. 3C, for example. Also, as shown in FIG. 3D,
a resistance element 136 and a constant current source 137 may be
employed to utilize voltages generated at both ends of the
resistance element 136, for example. The constant current source
137 may employ a transistor 138 and another reference voltage
generating circuit 139, as shown in FIG. 3E, so that a desired
reference voltage Vref2 can be generated utilizing a reference
voltage (Vref2') that is used in other portions in the power supply
device or the like. Further, as shown in FIG. 3F, a resistance
element 140 and a Zener diode 141 may be used, for example.
[0092] Operations of the Active Power Supply Device 111 in the
First and the Second Operation Modes
[0093] In a case where the active power supply device 111 is in the
first operation mode, i.e., in a case where it supplies a power
that is required when the load circuit 101 is in an active state,
the output switch 116 and the switch 124a are turned on whereas the
switch 124b is turned off under the control of the operation mode
switching signal 117, as shown in FIG. 2A. In this case, the output
voltage Vout is fed back to the differential operational amplifier
122, and the differential operational amplifier 122 applies a
control voltage to the gate terminal of the output transistor 125
so that the output voltage Vout becomes equal to the reference
voltage Vref1. Then, the output transistor 125 converts the voltage
of the power supply 113 into a voltage that is equal to the
reference voltage Vref1, and the converted voltage is supplied to
the load circuit 101.
[0094] When the active power supply device 111 is in the second
operation mode, i.e., when the load circuit 101 is in a standby
state and the power supply from the active power supply device 111
is not required, the output switch 116 is turned off to cut off the
power supply while the switch 124a is turned off and the switch
124a is turned on to supply the reference voltage Vref2 to the gate
terminal of the output transistor 125, as shown in FIG. 2B. As
mentioned above, the reference voltage Vref2 is approximately the
same voltage as a voltage that is output from the differential
operational amplifier 122 (that is input to the gate terminal of
the output transistor 125) when the voltage converting circuit 114
is in the first operation mode and in a steady state. Therefore,
the output transistor 125 is maintained in substantially the same
state as that in the first operation state, except that electric
current does not flow between the source and the drain. As a
result, when the active power supply device 111 is shifted to the
first operation mode, a voltage that is equal to the reference
voltage Vref1 is promptly supplied to the load circuit 101 as the
output voltage Vout.
[0095] Specifically, in conventional cases where the gate voltage
is shifted to H level (high level) to turn off the p-type MOS
output transistor, when the feedback control signal is input to the
gate terminal, the state in which the gate voltage has been stuck
on H level does not immediately go away as shown by the broken line
in FIG. 4, for example. Therefore, as is clearly seen from the
figure, it takes a long time to obtain an appropriate output
voltage. This tendency is more apparent particularly when the
output current is large, since the size of the output transistor
125 is large and the parasitic capacitance is accordingly large. In
contrast, when, as described above, the gate voltage of the output
transistor 125 is maintained at the reference voltage Vref2 during
the second operation mode, the gate voltage does not vary much
after entering the first operation mode, and consequently, the
output voltage Vout rises and the feedback control enters a steady
state within a short time, so that a stable voltage supply is
started, as shown by the solid lines in FIG. 4. It should be noted
that the provision of the output switch 116 does not reduce the
response speed because it can be turned on/off at high speed by
driving it with an element having a large number of fan outs.
[0096] Operations of the Active Power Supply Device 111 and the
Standby Power Supply Device 112
[0097] Both output voltages Vout of the active power supply device
111 and the standby power supply device 112 quickly rise as
described above, and therefore, output voltage drops (and
overshoots) do not easily occur when, for example, either of the
active power supply device 111 and the standby power supply device
112 enters the first operation mode and the other enters the second
operation mode according to load fluctuation. More specifically,
for example as shown in FIG. 5, when a load current is small, the
standby power supply device 112 enters the first operation mode and
the active power supply device 111 enters the second operation
mode, whereas when the load current is large, they are switched the
other way round. Since the output voltage of one of the power
supply devices that changes into the first operation mode rises at
approximately the same time as the output voltage of the other
power supply device that changes into the second operation mode
drops. As a consequence, little decrease is seen in the output
voltage Vout of the power supply device as a whole, as shown in the
figure.
[0098] In contrast, as shown in FIG. 6, in the case where the gate
voltage of the p-type MOS output transistor, for example, is turned
to H level when the power supply is stopped as is the case with
conventional power supply devices, the output voltage of the power
supply device that is changed from a suspend state into a supply
state requires a certain period of time until it rises as already
described above, although the output voltage of the power supply
device that has been in a power supply state drops relatively
immediately. Therefore, a voltage drop is caused in the output
voltage of the power supply device as a whole. In both cases where
the load current increases and decreases, the voltage drop such as
this similarly occurs according to the switching of the power
supply devices. In view of this problem, it might be conceivable to
delay one of the power supply devices entering the suspend state
until the other power supply device that enters the power supply
state reaches a steady state. However, even if a power supply
device for a small power is maintained in a power supply state as
the load current increases, it is difficult to suppress the
reduction in the output voltage because its driving capability is
small. Conversely, when a power supply device for a large power is
maintained in a power supply state as the load current decreases,
an excessive output voltage increase (overshoot) can be caused. For
these reasons, it is difficult to maintain the output voltage at a
constant level in such a case described above where the gate
voltage of the p-type MOS output transistor, for example, is turned
to H level when in a suspend state of power supply. It might also
be conceivable that for example, a power supply device for a small
power is constantly maintained in a power supply state, regardless
of the load fluctuation, but this necessitates a wasteful quiescent
current consumption. On the contrary, when the gate voltage of the
output transistor 125 is maintained at a predetermined voltage as
described above, a voltage drop in the output voltage Vout that
occurs at the switching of the power supply devices according to
step-like load fluctuations can be easily suppressed over a wide
range of load current while a high current efficiency is
maintained.
[0099] Embodiment 2
[0100] The foregoing embodiment 1 has described an example in which
the voltage of the gate terminal of the output transistor 125 is
maintained at a predetermined voltage during the second operation
mode. The present embodiment describes an example configured such
that nodes other than the gate terminal are also maintained at a
predetermined voltage. In the following embodiments, similar parts
to those of the foregoing embodiment 1 and so forth are designated
by the same reference characters and are not further elaborated
on.
[0101] A power supply device 211 of Embodiment 2 is configured such
that, as shown in FIG. 7 which shows the state during the second
operation mode, the output voltage Vout is not directly supplied to
the differential operational amplifier 122 unlike the power supply
device of Embodiment 1, but the output voltage Vout is divided by
resistance elements 221 and 222 (a voltage of the connecting points
between the resistance elements 221 and 222) and is supplied
thereto. When such a divided voltage is fed back, highly accurate
output voltage can be easily obtained at 1.5 V or higher by using a
bandgap reference at about 1.5 V for the reference voltage Vref1. A
capacitor 223 is provided between the connecting point of the
resistance elements 221 and 222 and the output terminal 115. A
reference voltage generating circuit 225 that generates a reference
voltage Vref3 is connected to the connecting point (in other words,
a terminal 223a of the capacitor 223) via a switch 224. Further,
switches 226 and 227 are provided at both sides of the resistance
elements 221 and 222 for cutting off a leakage current path from
the load circuit 101 and the reference voltage generating circuit
225 (from both ends of the capacitor 223) during the second
operation mode.
[0102] In this power supply device 211, the reference voltage Vref1
that is supplied from the reference voltage generating circuit 121
to the differential operational amplifier 122 is equal to a voltage
obtained by dividing the voltage to be output as the output voltage
Vout using the resistance elements 221 and 222. Meanwhile, the
reference voltage generating circuit 225 is configured so as to
generate a reference voltage Vref3 that is substantially equal to
the voltage of the terminal 223a of the capacitor 223 when the
power supply device 211 is in the first operation mode and in a
steady state (this voltage is consequently a voltage equal to the
reference voltage Vref1). During the second operation mode, this
reference voltage Vref3 is applied to the terminal 223a of the
capacitor 223 via the switch 224.
[0103] In the power supply device configured in the above-described
manner, when it shifts from the second operation mode to the first
operation mode, the switches 124a, 116, 226, and 227 are turned on
whereas the switches 124b and 224 are turned off. Under this
condition, if electric charge has not been stored in the capacitor
223, the feedback control does not enter a steady state and an
appropriate output voltage Vout cannot be obtained until a
predetermined charge is stored. However, as described above,
because the reference voltage Vref3 is applied to the terminal 223a
of the capacitor 223 during the second operation mode, the
capacitor 223 is maintained in a charged state that is
approximately the same state as the steady state during the first
operation mode. In addition, the gate voltage of the output
transistor 125 is maintained at a reference voltage Vref2 as in
Embodiment 1. Therefore, after entering the first operation mode,
the output voltage Vout quickly rises and the feedback control
quickly enters a steady state, so that a stable voltage supply can
be started. Moreover, in cases where a plurality of power supply
devices are switched, a voltage drop in the output voltage Vout can
be easily suppressed.
[0104] Modified Example
[0105] As discussed above, the reference voltage Vref3 is
preferable to be set at a voltage substantially equal to the
reference voltage Vref1. For this reason, the reference voltage
generating circuit 121 may also serve as the reference voltage
generating circuit 225, as shown in FIG. 8. Specifically, this is
achieved by providing a switch 228 that is brought into a
conducting state during the second operation mode to connect the
output (the reference voltage Vref1) of the reference voltage
generating circuit 121 and the terminal 223a of the capacitor 223.
By employing this configuration, the same effects can be attained
with a fewer number of elements than the previously-described
configuration. It should be noted, however, that the reference
voltage Vref1 has a larger influence on the accuracy of the output
voltage Vout than the reference voltage Vref3. For this reason, in
such cases that great accuracy and stability are required in the
voltage control, it may be preferable that the reference voltage
generating circuit 121 be provided independently as shown in FIG.
7.
[0106] Modified Examples in the Cases of a Plurality of Unit Power
Supply Devices
[0107] When two or more unit power supply devices are provided and
the output voltage Vout is divided and fed back to the differential
operational amplifier in each unit power supply device in a similar
manner, a voltage that is divided and used for the feedback in a
unit power supply device that is in the first operation mode can be
used for maintaining a voltage at a predetermined node of another
unit power supply device that is in the second operation mode.
[0108] Referring to FIG. 9, a power supply device 311 has a similar
configuration to the power supply device 211 of the above-described
example (FIG. 7), and the only difference is that a voltage that is
input from a power supply device 312 via the switch 224 is used in
place of the reference voltage Vref3 generated by the
above-described reference voltage generating circuit 225.
[0109] Like the power supply device 311, the power supply device
312 is configured such that the output voltage Vout is divided by
the resistance elements 221 and 222 and is fed back to the
differential operational amplifier 122, and the divided voltage is
given to the switch 224 of the power supply device 311. It should
be noted that, for the sake of simplicity in illustration, the
figure depicts an example of the power supply device 312 in which
the switches 226 and 227, and the capacitor 223 are not provided
and the state inside is not maintained in the same state as that in
the first operation mode, but the present invention is not so
limited, and a power supply device having a similar configuration
to the power supply device 311 may be employed.
[0110] With this configuration, when the power supply device 311 is
in the first operation mode, the switch 224 is brought into a
non-conducting state and the operation is exactly the same as the
above-described power supply device 211; the output voltage Vout
controlled by the output transistor 125 is output to the load
circuit 101. Under this confidtion, in the power supply device 312,
the output switch 116 is brought into a non-conducting state, and
consequently the power supply device 312 enters a state in which it
stops the power supply.
[0111] In contrast, when the power supply device 311 enters the
second operation mode and the power supply device 312 enters a
state in which it supplies power, the switch 224 is, as shown in
FIG. 10, brought into a conducting state so that the voltage at the
connecting point of the resistance elements 221 and 222 in the
power supply device 312 is applied to the terminal 223a of the
capacitor 223 via the switch 224. Accordingly, the capacitor 223 is
maintained at approximately the same voltage at both ends (in a
charged state) as in the steady state in the first operation mode.
In addition, the gate voltage of the output transistor 125 is
maintained at the reference voltage Vref2 by the reference voltage
generating circuit 123. Therefore, when entering the first
operation mode, a stable voltage supply can be quickly started and
a voltage drop in the output voltage Vout can be suppressed. It
should be noted that even when the voltage of the capacitor at both
ends thereof is maintained in the above-described manner, a
wasteful quiescent current consumption does not occur since there
is no current path.
[0112] Embodiment 3
[0113] As well as the foregoing embodiments, Embodiment 3 describes
a power supply device that can improve the response characteristics
when the device is switched from the second operation mode to the
first operation mode and can reduce power supply device during the
second operation mode.
[0114] Referring to FIGS. 11A and 11B, a power supply device 411 is
similar to the active power supply device 111 according to the
foregoing embodiment 1 (FIG. 2), but differs therefrom in that
switches 421 and 422 (power consumption reducing means) are
provided, for example, between the power supply device 113 and the
reference voltage generating circuit 121 and between the supply
device 113 and the differential operational amplifier 122,
respectively. The switches 421 and 422 are brought into a
conducting state during the first operation mode as shown in FIG.
11A to supply power to the load circuit 101 exactly in the same
operation as that of the active power supply device 111. On the
other hand, during the second operation mode, the switches 421 and
422 are brought into a non-conducting state as shown in FIG. 11B to
cut off the power supply to the reference voltage generating
circuit 121 and the differential operational amplifier 122, etc.
However, the reference voltage generating circuit 123 needs to
maintain the gate voltage of the output transistor 125 as described
above and is therefore kept connected to the power supply 113. As a
result, the current (quiescent current) required for the operation
of the power supply device 411 itself during the first operation
mode and during the second operation mode is as shown in FIGS. 12A
and 12B; the current during the second operation mode (as
represented by B in the figure) can be reduced to at least the same
level to that during the first operation mode (as represented by A
in the figure) or lower, and can even be easily reduced to a
remarkably lower level.
[0115] As described above, the connections to the power supply 113
are brought into an OFF state to cut off the current paths of the
power supply except the portion that is required to improve the
response characteristic when entering the first operation mode, and
thereby, the power consumption during the second operation mode can
be reduced without degrading the response characteristic.
[0116] It should be noted that, in place of providing the switches
421 and 422 for cutting off the current paths that has little or no
effect on the response characteristic at the power supply 113
sides, switches 423 and 424 may be provided at the grounding side.
It is also possible to provide the switches both at the power
supply side and at the grounding side.
[0117] In addition, the power supply to the reference voltage
generating circuit 123 for maintaining the gate voltage of the
output transistor 125 at the reference voltage Vref2 may be cut off
during the first operation mode in a similar manner.
[0118] Example of a Power Supply Device Having a Third Operation
Mode
[0119] In the following, a power supply device is discussed which
has a third operation mode (non-operating mode), in addition to the
first and the second operation modes, in which power is not
supplied to the load circuit 101 and there is no quiescent power
consumption.
[0120] A power supply device 510 has, for example, a voltage
controlling circuit 511, an output transistor 125, an output switch
116, an output terminal 115, and switches 512 to 514, as shown in
FIG. 14. The voltage controlling circuit 511 has a reference
voltage generating circuit, a differential operational amplifier,
and so forth such as described in the foregoing embodiments, and is
configured to be switched between the first and the second
operation modes in a similar manner to the active power supply
device 111 (of FIG. 2) etc. In addition, in response to a third
operation mode signal 515, the switches 512 and 513 are turned off
to cut off all the current paths from the power supply 113 while
the switch 514 is turned on to fix the voltage of the gate terminal
of the output transistor 125 at the voltage of the power supply
113, so that the output transistor 125 is turned off, and the
output switch 116 is turned off. Thus, the third operation mode is
entered in which there is no power supply or no quiescent power
consumption. It should be noted here that, in place of fixing the
voltage at the gate terminal, the source of the output transistor
125 may be cut off from the power supply 113. When these switches
are formed on a p-type semiconductor substrate, it is preferable
that the switch 512 at the power supply side be a p-type MOS
transistor switch, the switch 513 at the grounding side be a n-type
MOS transistor switch, and the output switch 116 be a transfer gate
using both p-type and n-type MOS transistor switches, although
various other configurations are possible.
[0121] The above-described third operation mode can be used, for
example, when power does not need to be supplied immediately to the
load circuit, to prevent power consumption of the power supply
device itself. In addition, by preventing currents from flowing
into the power supply device in this manner, a leakage test can be
easily conducted to confirm if there is no leakage current.
[0122] Another Example Capable of Reducing Power Consumption
[0123] An example of a differential operational amplifier 122 is
discussed which can easily attain both an improvement of response
characteristic and a reduction in quiescent current
consumption.
[0124] The differential operational amplifier 122 of this example
is, for example as shown in FIG. 15A, configured to have n-type MOS
transistors 431, 431 that constitute a differential amplifier
circuit, p-type MOS transistors 432, 432 that constitute a current
mirror circuit, and an n-type MOS transistor 433 that controls a
bias current. To the gate of the n-type MOS transistor 433, a
variable bias voltage-generating circuit 434 (bias current
controlling means) is connected. The variable bias
voltage-generating circuit 434 has, for example as shown in FIG.
15B, an n-type MOS transistor 435 that constitutes a current mirror
circuit together with the n-type MOS transistor 433, and a current
source 436 that is variable in response to a load current flowing
in the load circuit 101, an operation switching signal, or the
like.
[0125] With this configuration, the variable bias
voltage-generating circuit 434 outputs a voltage corresponding to
the current supplied by the current source 436, and a bias current
corresponding to this voltage flows in the differential operational
amplifier 122.
[0126] Accordingly, for example, if the voltage output from the
variable bias voltage-generating circuit 434 is made low when the
load current flowing in the load circuit 101 is small or when the
power supply device is in the second operation mode, the bias
current of the differential operational amplifier 122 becomes
small, and thus power consumption is reduced. On the other hand, if
the voltage output from the variable bias voltage-generating
circuit 434 is made high when the load current is large or when the
power supply device is in the first operation mode, the bias
current becomes large and thus the response characteristic of the
differential operational amplifier 122 increases; therefore a
stable voltage can be easily output even at the switching between
the operation modes or at sudden load fluctuations.
[0127] The bias current of the differential operational amplifier
122 may be controlled through feedback control according to the
magnitude of the load current. Specifically, for example, a power
supply device 451 shown in FIG. 16 uses a differential operational
amplifier 122 that is shown in FIG. 15 as the differential
operational amplifier 122 of the active power supply device 111
shown in FIG. 2. In addition, the power supply device 451 has an
n-type MOS transistor 452 that constitutes a current mirror circuit
together with the n-type MOS transistor 433 of the differential
operational amplifier 122, and a p-type MOS transistor 453 that
supplies a current corresponding to the gate voltage of the output
transistor 125 to the n-type MOS transistor 452. In the power
supply device 451 thus configured, as the voltage applied to the
gate of the output transistor 125 (and the gate of the p-type MOS
transistor 453) is lower, in other words, as the load current is
larger (in this case, the fluctuation of the load current is
generally large), the bias current flowing via the n-type MOS
transistor 433 of the differential operational amplifier 122
becomes larger and therefore the response characteristic improves.
Thus, it is easily made possible to achieve a power supply that can
follow sudden load fluctuations. On the other hand, when the load
current is small, the bias current becomes small and power
consumption can be therefore reduced. In this example, in addition
to the control of the bias current according to the load current,
the device may be configured to forcibly vary the bias current or
the mirror ratio of the n-type MOS transistors 433 and 452 may be
configured to be variable. Moreover, if the configuration as
described above is applied to the previously-described
configuration of FIG. 7, stability is further improved since
instability in the feedback control can be suppressed by the
improvement in the response characteristic.
[0128] Embodiment 4
[0129] To be precise, in the power supply devices described in
Embodiment 1 etc., for example, the gate voltage of the output
transistor 125 during the first operation mode changes according to
the magnitude of the load current flowing in the load circuit 101.
Therefore, in the case where the magnitude of the load current
during the first operation mode is known beforehand, the
fluctuation of the output voltage Vout after the operation mode
switching can be suppressed more reliably if a voltage
corresponding to the magnitude of the load current is generated as
the reference voltage Vref2 or the like and is applied to the gate
terminal of the output transistor 125 or the like, when entering
the first operation mode from the second operation mode.
[0130] The case where the magnitude of the load current is known
beforehand refers to such a case that, for example, when the
apparatus that is the load circuit 101 enters an active state, the
circuits or the like operating under the active state can be
specified according to the conditions of the apparatus, the
environment, or the like. More specifically, such a case is
included, for example, that it has been determined that when the
apparatus enters an active state, the operation control portion and
the display portion are in an operating state. In such cases, the
magnitude of the load current can be easily determined or
estimated.
[0131] Next, a specific example is described in which the reference
voltage Vref2 is determined according to the magnitude of the load
current. The gate voltage of the output transistor 125 during the
first operation mode becomes lower when the load current is larger
in the case of a p-type MOS transistor. In consideration of this,
for example as shown in FIGS. 17A to 17C, in the second operation
mode, a voltage corresponding to a presupposed load current is
generated as the reference voltage Vref2, and the generated voltage
is input to the gate terminal of the output transistor 125. Thus,
as seen in the figure, the gate voltage does not fluctuate when
entering the first operation mode, and consequently, upon entering
the first operation mode, a steady state is quickly attained and a
stable voltage supply is started.
[0132] The reference voltage generating circuit 123 that generates
a variable reference voltage Vref2 may be configured, as shown in
FIG. 18A, such that the voltage of the power supply 113, etc. is
divided by the resistance element 131 and a variable resistance
element 151 in which the resistance value varies in response to a
resistance value controlling signal. The variable resistance
element 151 can be configured by connecting the sources and the
drains of p-type MOS transistors 153 to either end of resistance
elements 152 that are connected in series, as shown in FIG. 18B,
and the resistance value as a whole is made variable by turning
on/off the p-type MOS transistors 153 with the resistance value
controlling signal. Alternatively, as shown in FIG. 18C, using a
resistance element 154 and a variable current source 155, a voltage
that is generated at either end of the resistance element 154 may
be utilized.
[0133] Embodiment 5
[0134] Embodiment 5 describes an example of a power supply device
that comprises a greater number of various unit power supply
devices and can supply power according to a plurality of load
current states in the circuits or devices to which power is
supplied. Specific examples of the plurality of load current states
include, for example in the case of computers or the like, an
active state in which normal operation is performed (including a
state in which hard disks are operated, a state in which data
transmission is carried out via networks, a state in which
keyboards are operated, and so forth), a state called "sleep" or
"standby" in which surface operations are suspended while the
states and data inside are retained, a shut-down state in which
virtually all the operations are shut down except small portion of
the functions such as a timekeeping function, and so forth. In the
case of mobile telephones, the plurality of load current states
include a talk state that accompanies the transmission of radio
waves, a standby state in which only incoming transmission and
operating inputs are accepted, and a shut down state in which all
the operations except data retention are shut down. In addition,
even in a single device, LSIs that constitute the device may enter
separate operating states.
[0135] Configuration of a Power Supply Device Including a Plurality
of Unit Power Supply Devices
[0136] As shown in FIG. 19, a power supply device 500 is provided
with four or more power supply devices 501 to 504, etc. each being
a unit power supply. The output terminals 115 of the power supply
devices 501 to 504 are connected to each other so that an output
voltage Vout can be supplied to the load circuit 101. The power
supply device 500 is also provided with an operation mode
controlling unit 505 that controls the operation modes or the like
of the power supply devices 502 to 504. The operation mode
controlling unit 505 may be configured to control the operation
modes based on the operating states and operating sequences of the
load circuit 101, or may be configured to control the operation
modes by detecting the actual load current flowing in the load
circuit 101.
[0137] The power supply device 501 is a power supply device that
has only the first operation mode and supplies power continuously
as conventional devices, and such a power supply device may be used
in the power supply device 500. In addition, it is also possible to
use a power supply device that enters a power suspend state merely
by cutting off the power supply voltage (a power supply device that
does not have a good response characteristic but has a simple
construction) according to the intended use or the like of the
circuit or apparatus that is the load circuit 101. Furthermore, a
power supply device that outputs a different voltage from the
voltages output from the other power supply devices may be used
when, for example, the supplied voltage needs to be varied
according to the conditions or the like of the load circuit
101.
[0138] The power supply devices 502 and 503 are such power supply
devices as described in the foregoing embodiments having the first
and the second operation modes, and the power supply device 504 is
a power supply device having the first to the third operation
modes.
[0139] Selection of the Power Supply Device that is Brought into
the First Operation Mode
[0140] Next, the selection of a plurality of power supply devices
502, etc. is explained below.
[0141] First, it is necessary that the power supply device(s) 502,
etc. that is/are selected to supply power (that enter/enters the
first operation mode) have a current capacity according to the load
current flowing in the load circuit 101. Here, the power supply
device(s) to be selected is not limited to one device, but a
plurality of devices may be selected in combination. Specifically,
when the output voltages from the devices are equal, the resultant
current capacity is the total of the capacities of the power supply
devices 502, etc., and therefore, it is only necessary that this
resultant current capacity is an amount that corresponds to the
load current flowing in the load circuit 101. However, when power
supply devices having different output voltages are present, it is
necessary that a power supply device having a different output
voltage be not connected to another power supply device.
[0142] In addition, when there are a plurality of combinations that
satisfy a required current capacity, it is preferable that a
combination having a small quiescent current be selected.
Specifically, when the power supply devices 502, etc. are in the
second operation mode, the power supply devices 502, etc.
themselves consume electric power as mentioned above, though the
amount is insignificant. Accordingly, in order to select the
optimum combination of the power supply devices 502, etc., it is
preferable that the grand total of the total quiescent current of
the power supply devices 502, etc. that enter the first operation
mode and the total quiescent current of the power supply devices
502, etc. that enter the second operation mode be minimized.
[0143] Specifically, for example, regarding power supply devices P
and Q, assuming that:
[0144] in the power supply device P, the quiescent currents
consumed during the first operation mode and the second operation
mode are 10 mA and 1 mA, respectively, and
[0145] in the power supply device Q, the quiescent currents
consumed during the first operation mode and the second operation
mode are 15 mA and 12 mA, respectively,
[0146] (1) when the power supply device P is in the first operation
mode whereas the power supply device Q is in the second operation
mode, the total of the current consumed is:
10mA+12mA=22mA.
[0147] (2) on the other hand, when the power supply device Q is in
the first operation mode whereas the power supply device P is in
the second operation mode, the total of the current consumed
is:
1mA+15mA=16mA.
[0148] In other words, the power supply device P has a smaller
quiescent current in the case where power is supplied in the first
operation mode, but under this condition, if the power supply
device Q enters the second operation mode, a quiescent current of
12 mA flows, and accordingly, the power consumption as a whole can
be reduced if power is supplied by the power supply device Q.
[0149] Thus, by selecting optimum power supply devices so that a
required current capacity is satisfied and the quiescent current
consumption of the whole power supply device is minimized, a
voltage drop in the output voltage Vout can be suppressed and a
high current efficiency can be obtained over a wide range of load
current.
[0150] Selection According to the Retained Gate Voltage
[0151] For example, when two or more of the power supply devices
502 to 504 have a required current capacity, the reference voltage
Vref2 that is applied to the gate terminal of the output transistor
125 may be varied by the reference voltage generating circuit 123,
and, according to the voltage and the load current, the optimum
power supply devices can be selected from the power supply devices
502 to 504.
[0152] It should be noted here that fluctuations of the gate
voltage and the output voltage Vout after switching the operation
modes can be suppressed by setting the gate voltage according to
the load current, and this principle is the same as described in
the foregoing embodiment 4 (FIG. 17). In other words, the foregoing
embodiment 4 has described an example in which the gate voltage is
set to be variable in one power supply device, but the present
embodiment achieves similar effects by setting predetermined gate
voltages for the respective power supply devices 502 to 504. (It
should be noted that, in addition, each of the power supply devices
502 to 504 may be configured to have a variable gate voltage, as in
the manner shown in Embodiment 4.)
[0153] FIGS. 20A to 20C illustrate the relationship between the
gate voltage of the output transistor 125 and the load current in
the first operation mode. As seen from the figure, in response to
the load current that has fluctuated, optimum power supply devices
are selected from the power supply devices 502, etc. such that
variation in the output voltage is minimized according to the load
current that has fluctuated, and the selected power supply devices
enter the first operation mode. Thus, even after the switching of
operation modes, the gate voltage shows little fluctuation, and
therefore, a steady state can be quickly reached and a stable
voltage supply is started. It should be noted that those power
supply devices that have not been selected may remain in the second
operation mode, or may enter the third operation mode.
[0154] As described above, when at least one or more power supply
devices 502, etc. are selected according to the gate voltage to
enter the first operation mode, a smooth switching from the second
operation mode to the first operation mode can be ensured without
fluctuations in the gate voltage of the output transistor, and a
voltage drop in the output voltage Vout can be suppressed.
[0155] Example of Operation Mode Transition
[0156] Discussed below is an example of transition of operation
modes in the power supply devices 501, etc. in response to load
current fluctuations.
[0157] If the load current of the load circuit 101 changes as shown
in FIG. 21, for example, operation modes of the power supply
devices 502 to 504 accordingly changes. (The power supply device
501 is continuously in a power supply state and is therefore not
further elaborated in the following discussion.)
[0158] When the load current is small, the power supply device 502,
for example, enters the first operation mode to supply power to the
load circuit 101. Under this condition, the power supply device 503
enters the second operation mode and the quiescent current
consumption is suppressed. In addition, the power supply device 504
having three operation modes enters the third operation mode if it
is found that the load current does not increase, and the quiescent
current consumption is further suppressed. The power supply device
504 enters the second operation mode in advance if it is found that
the load current increases or if there is a possibility that the
load current increases, in order to prepare for the start of power
supply. More specifically, for example in the case of a mobile
telephone, the power supply device that supplies electric power to
the transmitter circuit is in the third operation mode during the
standby state of the telephone, but when the key operation is
carried out, the power supply device enters the second operation
mode since transmission might be subsequently performed.
[0159] Then, when the load current increases, the power supply
devices 503 and 504 are shifted from the second operation mode to
the first operation mode while the power supply device 502 enters
the second operation mode. Thus, a required power supply is
promptly started without causing a voltage drop in the output
voltage Vout or the like.
[0160] When the load current decreases, the power supply devices
503 and 504 are shifted back to the second operation mode and the
third operation mode, respectively, but in this case as well, the
power supply device 502 is shifted from the second operation mode
to the first operation mode, so that power supply is quickly
started. Thus, even when the power supply from the power supply
devices 503 and 504 suddenly stops, a voltage drop in the output
voltage Vout or the like is prevented. In this case, when the power
supply device 504 stops power supply, it may enter either the
second operation mode or the third operation mode. In other words,
either operation mode may be selected according to the possibility
of a load current increase or the like.
[0161] Embodiment 6
[0162] Embodiment 6 describes examples of the forms of mounting the
above-described power supply devices on an LSI (large scale
integrated circuit) chip.
[0163] As shown in FIG. 22, by forming one or more power supply
devices 601 and 602 on an LSI chip 600, it is possible to configure
a power supply LSI that has an improved response characteristic and
can supply power without causing a voltage drop in the output
voltage Vout according to load current fluctuations.
[0164] As shown in FIG. 23, in addition to the power supply devices
601 and 602, it is possible to form, on the same LSI chip 610, a
load circuit core 603 that is a load circuit driven by these power
supply devices and a load circuit core 604 that is driven by
another voltage. Furthermore, with the use of the power supply
devices 601 and 602 having good response characteristics as
described above, the capacitance required for the capacitor 605
that is a power supply capacitance of the load circuit can be made
small. Therefore, the power supply devices can be easily integrated
inside the LSI chip 610 unlike conventional examples in which they
are externally connected thereto. Hence, it is made possible to
reduce the fabrication cost and the size of the apparatus that uses
such an LSI chip 610.
[0165] It should be noted that, although in the above-described
example, the gate voltage (reference voltage Vref2) of the output
transistor 125 during the second operation mode is set to be
substantially the same voltage as the gate voltage during the first
operation mode, the embodiment is not limited thereto. If the
reference voltage Vref2 is set according to the following
expression:
.vertline.V1-Vref2.vertline.<.vertline.Voff-V1.vertline.
[0166] where V1 is the gate voltage during the first operation mode
and Voff is a power supply voltage (H level) or a ground voltage (L
level) at which the output transistor 125 is completely in an OFF
state, the rise time of the output voltage Vout can be shortened
than in the case where the gate voltage is set to be Voff. In
addition, when the reference voltage Vref2 is set according to the
following expression:
.vertline.V1-Vref2.vertline.<.vertline.V2-V1.vertline.
[0167] where V2 is the gate voltage corresponding to the load
current flowing during the second operation mode, the rise time of
the output voltage Vout can be shortened than in the case where the
gate voltage is set to be V2. In addition, when the gate voltage
becomes a high impedance and an indefinite voltage, the rise time
accordingly becomes indefinite. With the above-described
configuration, however, the rise time can be managed at a certain
time by setting the gate voltage at a predetermined voltage.
[0168] In these cases, as described above, when the gate voltage of
the output transistor 125 is closer to the gate voltage during the
first operation mode, the rise time of the output voltage Vout is
shorter. In practice, the specific setting of the reference voltage
Vref2 may be carried out as follows. The amount of fluctuation of
the power supply voltage in the case where the load current
fluctuates also depends on the amount of fluctuation of the load
current and the capacitance of the capacitor 102. For this reason,
the reference voltage Vref2 can be set so that the amount of
fluctuation of the power supply voltage is smaller than the amount
of fluctuation of the power supply voltage that can be permitted in
the apparatus to which power is supplied. This means, conversely,
that when the reference voltage Vref2 is closer to the voltage V1,
the capacitance of the capacitor 102 can be made smaller, and as a
consequence, the integration of the capacitor 102 in an LSI and a
reduction of the area in the LSI occupied by the capacitor 102 can
be easily achieved.
[0169] The setting of the reference voltage and its advantageous
effects can be also applied to, for example, the reference voltage
Vref3 that is applied to the terminal 223a of the capacitor 223,
which has been explained in Embodiment 2 above.
[0170] In addition, the constituting elements that have been
described in the foregoing embodiments may be combined together as
necessary. Specifically, for example, the configurations described
in Embodiment 3 (such as shown in FIG. 11) in which the current
paths that have little or no effect on the response characteristic
are cut off may be applied to the power supply device of Embodiment
2 (FIG. 7).
[0171] Further, in the above-described example, the output
transistor 125 is described as a p-type MOS transistor, but the
present invention is not limited thereto and can be applied to such
a case of a power supply device 461 shown in FIG. 24, which uses a
bipolar-type output transistor 462.
[0172] As has been described above, the present invention achieves
a power supply device in which the output voltage can rise fast, an
output voltage drop can be avoided or reduced at the switching
between current supply states or the like, a high current
efficiency can be achieved over a wide range of load current
without causing a considerable increase in the quiescent current
consumption in the power supply device itself, and moreover the
device can be easily integrated into a single chip.
[0173] The invention may be embodied in other forms without
departing from the spirit or essential characteristics thereof. The
embodiments disclosed in this application are to be considered in
all respects as illustrative and not limiting. The scope of the
invention is indicated by the appended claims rather than by the
foregoing description, and all changes which come within the
meaning and range of equivalency of the claims are intended to be
embraced therein.
* * * * *